RU2172494C2 - Device for determination oflocation and method for request for rendering of service in determination of location for mobile communication system - Google Patents

Abstract

FIELD: mobile communication systems. SUBSTANCE: the switching center of mobile parties makes a request for rendering of service in determination of location in the base station controller, in response the base station controller makes a request for assignment of a channel for the mobile station at least in two adjacent base transceiving stations. If the adjacent base transceiving stations connect a channel and send a reply signal to the base station controller, the latter generates a command to the base transceiving stations for a request of a signal with a power switching function. The servicing base transceiving station generates a command to the mobile station for transmission of a signal with a power switching function in accordance with the command of the base station controller. The mobile station transmits the signal with a power switching function to the servicing base transceiving station and adjacent base transceiving stations in accordance with the command of the servicing base transceiving station. The servicing base transceiving station and the adjacent base transceiving stations detect the parameters requested for determination of location with the aid of reception of the signal with a power switching function with a different time delay respectively. The servicing base transceiving station and the adjacent base transceiving stations transmit a message to the base station controller on the detected parameters, the base station controller transmits the parameters that are transmitted from the servicing base transceiving stations and the adjacent base transceiving stations to the switching center of mobile parties. Then, the switching center of mobile parties computes the location of the mobile station with the use of the obtained parameters. EFFECT: reduced equipment expenditures. 14 cl, 5 dwg

Description

FIELD OF THE INVENTION
The invention relates to the field of mobile telephone systems, and more particularly, to a method for confirming the location of a moving station in a mobile communication system.

State of the art
A known cellular radio communication system includes a mobile station (MS) that receives radio services, a base transceiver station (BTS) providing radio services for a mobile station (MS) within a specific area, a base station controller (BSC) connecting the BTS to the switching center mobile subscribers (CSC), and a mobile subscriber switching center (CSC) connecting the base station controller (BSC) to the public switched telephone network (PSTN).

 Recently, mobile communication systems providing new services have been commissioned. The location service, for example, allows you to determine the location of multiple mobile stations. This is useful in case of emergency calls in emergency situations, such as “119”, similar to “911” in the USA, or tracking unregistered subscribers, or in cases where physical distribution is required (that is, searching for stolen mobile stations or reporting registered mobile stations).

 In accordance with the known technology of the mobile communication network, the location of the mobile station is determined using a separate receiving device that each BTS is equipped with, and each BTS must receive radio waves emitted from the mobile station. The difference in arrival time (RVVP) occurs due to delays in the used radio waves, which are received in each of the many BTSs.

 For the system described above, the mobile station must emit a separate dedicated radio wave designed to provide location services. Therefore, the positioning system must be configured separately from the mobile network and, therefore, it is necessary to have duplicated hardware resources.

 US Pat. No. 5,614,914, “Wireless Telephone Distribution System with Spaced Time and Space Transmission for Determining the Location of a Receiver,” discloses a method for determining the location of a mobile station using a mobile station signal, which is received with a time delay in a plurality of antennas located separately in space from friend. However, the provision of a location service according to the disclosed method has the disadvantage of requiring a separate location system. Accordingly, it is an object of the present invention to provide a system and method for providing location services in an existing mobile communication system without the need for separate dedicated hardware.

SUMMARY OF THE INVENTION
The present invention provides a new positioning system, which allows you to calculate and recognize the location of a mobile station (MS) in a mobile communication network. In addition, the present invention provides a method that allows a mobile subscriber switching center (MSC) to request a location service in accordance with the needs of a mobile station or network.

According to one aspect of the present invention, a mobile communication system includes
at least three base transceiver stations (BTSs) receiving a signal with a power-on function (FWP) received from a mobile station along with detection parameters necessary to determine the location of the mobile station, and
Mobile Subscriber Switching Center (MSC), including means for calculating the location of a mobile station by receiving and combining detection parameters.

The present invention describes a preferred embodiment of a mobile communication system including a serving base transceiver station (BTS) connecting a channel for communicating with a mobile station, at least two neighboring BTSs adjacent to the serving BTS, a base station controller (BSC) the manager of the serving BTS and neighboring BTSs, and
Mobile Subscriber Switching Center (CSC) connecting the BSC to the public switched telephone network (PSTN), the method including the following operations
(a) make a request from the MSC for the provision of location services in the BSC, (b) make a request from the MSC for the allocation of a channel for a mobile station in neighboring BTSs, in accordance with a request from the MSC for the provision of a location service,
(c) connecting the channel between the mobile station and neighboring BTSs and sending a response signal to the BSC using the neighboring BTSs, in accordance with the request of the BSC in step (b),
(d) issue a command from the BSC serving the BTS to request a signal with a power-on function (PWF) from the mobile station,
(e) issue from the mobile station serving the BTS for transmitting the FWP signal in accordance with the BSC command in operation (d),
(f) transmitting the FWP signal to the serving BTS and to neighboring BTSs using the mobile station, in accordance with the command serving the BTS in step (e),
(g) detecting parameters using the serving BTS necessary to calculate the location of the mobile station, and by receiving a plurality of FWP signals transmitted from the mobile station, each FWP signal being transmitted with a different time delay,
(h) issue to the BSC a message about the detected parameters with the help of the serving BTS and neighboring BTS,
(i) transmit parameters reported from the serving BTS and neighboring BTSs to the MSC using the BSC, and
(j) calculating the location of the mobile station using the detected parameters using the DPC.

 According to one aspect of the present invention, a location service request request operation can be initialized as a request from a mobile station or when a network operator makes a request for location information of a mobile station.

 According to another aspect of the present invention, the first timer is activated after the BSC receives the location service request from the MSC, and stops at the time when the mobile station is again requested to provide the location service by the MSC or when the end of service message is issued location services for the mobile station.

 According to another aspect of the present invention, the BSC makes a request for at least two BTSs from among all BTSs included in the list of neighboring BTSs serving the BTSs in order to allocate a channel for the mobile station in operation (b).

 In another aspect of the present invention, the operation (d) issuing an BSC command to the serving BTS for requesting an FWP signal is performed by transmitting information about the FWP signal complying with the IS-95B standard to the serving BTS using the BSC.

 In an additional aspect of the present invention, the information of the FWP signal includes a power level interval, a time interval, and a transmission time.

 In another aspect of the present invention, the method further includes returning to operation (b) of channel allocation request for the mobile station in neighboring BTSs, in the case where the MSC re-requests the location service for the mobile station within the first predetermined time interval (first timer), wherein the first predetermined time interval is determined from the point in time when the CSC makes a request for the provision of location services in the BSC, to the point in time when the BSC receives from the CCP a signal for completing the location service.

 According to another aspect of the present invention, the method further includes an operation of completing a location service if the MSC does not re-request location services for the mobile station within the first predetermined time interval of the first timer since the MSC has requested the BSC to the provision of location services.

 In yet a further aspect of the present invention, the operation (g) of receiving the FWP signal by the serving BTS and neighboring BTSs further includes the operation of releasing, with the neighboring (neighboring) BTSs, a pre-allocated channel between the mobile station and the neighboring (neighboring) BTSs, which did not receive the FWP signal if at least one neighboring BTS does not receive the FWP signal after the mobile station transmits the FWP signal within a predetermined time, which is determined using the second timer.

 According to another aspect of the present invention, the method further includes an operation for completing the provision of a location service if the MSC requests to complete the provision of the location service within the critical time of the first timer, since the MSC has requested the BSC to provide the location service.

 According to the method of the present invention, the parameters are the time delay values of the PWF signal measured in each BTS.

 According to another aspect of the present invention, the operation (i) of transmitting parameters to the MSC further includes the operation of issuing a message to the MSC about the failure when the number of BTSs that carry information about the detected parameters for the BSC is less than or equal to two.

 According to another aspect of the present invention, the operation (i) of transmitting parameters to the MSC further includes the operation of issuing a command of at least one BTS that did not issue a message about the detected parameters, for reconnecting the channel to the mobile station using the BSC, when BTSs that carry information about the detected parameters for BSC are less than or equal to two.

Brief Description of the Drawings
The invention is illustrated by reference to the accompanying drawings, in which:
FIG. 1 shows a configuration of a positioning system for a mobile communication system according to the present invention;
FIG. 2 shows the reception of the FWP signal (power-on function) in a base transceiver station (BTS);
FIG. 3 depicts a graphical dependence of the level of received power of the high-frequency signal near each BTS from a distance;
FIG. 4 is a signaling message diagram illustrating a method for obtaining location services of a mobile subscriber switching center according to the present invention;
FIG. 5 is a diagram illustrating a request method for providing a location service of a mobile subscriber switching center according to the present invention.

Detailed Description of a Preferred Embodiment
The present invention discloses a method for providing a location service in a mobile communication system. Before describing the main method of the present invention, an explanation is given of the action of a signal with a power-on function (PF) and the operation of three timers used in the method of the present invention.

Signal with power on function (FVP)
In a cellular code division multiple access (CDMA) cellular system or in a personal communication service (PC) system supporting the IS-95B standard, as a wireless interface between the mobile station and the base transceiver station, the base transceiver station (BTS) may request a signal with the power-on function (FWP) in the mobile station, and the mobile station providing IS-95B can transmit the FWP signal in accordance with the BTS request.

 The FWP signal is the most powerful signal transmitted by the mobile station in accordance with the request of the BTS. The mobile station transmits a pulse in a certain time interval in which the pulse is gradually amplified at certain increments of the power level over a given time. Since the FWP signal is transmitted at a significantly higher power level than the common transmit signal of the mobile station, the BTS and neighboring BTSs can easily receive a signal.

Three timers
(1) First timer
Location: Base Station Controller (BSC)
Application: It is activated immediately after the request for the provision of location services from the switching center of mobile subscribers (MSC) and ends if it receives a message about the completion of the provision of location services from the MSC. If the first timer stops, the BSC terminates the provision of location services.

(2) Second timer
Location: Base Transceiver Station (BTS)
Application: It is activated immediately after the request for channel allocation from the base station controller (BSC), and ends if it receives the FWP signal from the mobile station. If the second timer completes, the adjacent BTS provides information to the BSC that the FWP signal has not been received.

(3) Third timer
Location: Mobile Station (PS)
Application: It is activated immediately after receiving the FWP message from the serving BTS, transmits the FWP signal and then shuts down. If the third timer ends its operation, the mobile station determines that the FWP signal was not transmitted.

 In FIG. 1 depicts a cellular telephone communication system for determining the location according to the present invention, which includes at least three BTSs 10, 11 and 12, each of which receives a signal with a power-on function (PWF) from a mobile station, each BTS additionally detects the parameters necessary to search for the location of the mobile station. That is, the BTS receives the FWP signal from the mobile station and measures the time of receipt of the FWP signal. The measured time is a parameter of the value needed to calculate the location of the mobile station, and the center of switching mobile subscribers (MSC) 30 includes a means for calculating the location of the mobile station by combining the parameters received from each of the three BTS 10, 11 and 12 through the controller base station (BSC) 20, a location database 32 located together with the MSC for storing and managing the calculated location data of the mobile station, a work and support center (CRC) 31, are located together with the CCP to ensure a single control position (that is, the operator receives information about the configuration status of the entire positioning system), control ability, status ("status"), alarm and diagnostic and message output functions, an application processor (PP) 41 dial-up Public Switched Telephone Network (PSTN) 40 to obtain the necessary information by organizing access to data from the database 32 of the location, as well as to maintain configuration support and system management my location.

 In the case where the mobile station is in communication with the BTS 10, the BTS 10 is considered to be serving the BTS. The serving BTS 10 transmits the FWP message to the mobile station to request the FWP signal through the forward traffic channel connecting the mobile station and the BTS in the case where the serving BTS 10 needs to have location information for the mobile station.

 If the mobile station receives the FWP message, then the level of the transmitted output signal increases for a short period of time within a certain time interval (third timer), then the FWP signal, which includes the preamble, is transmitted through the reverse traffic channel (that is, from the MS to the BTS )

 The third timer is activated immediately after the mobile station receives the FWP message from the BTS, and stops at the time when it transmits the FWP signal through the reverse traffic channel.

 Each of at least three BTSs 10, 11, and 12 located around the mobile station transmits an FWP message and receives the FWP signal, which is transmitted from the mobile station as a response. Each BTS measures the corresponding time delay (i.e., VP (time of arrival)) by dividing by 2 time intervals from transmitting the FWP message to receiving the FWP signal. The MSC 30 then calculates the location of the mobile station using the time delays measured at each BTS (i.e., BTS 10, 11, and 12).

 In FIG. 2 shows the acquisition of the FWP signal in the BTS. FIG. 2 depicts a mobile station 50 in communication with the BTS 10. The serving BTS 10 sends an FWP message to the mobile station 50. The mobile station 50, which receives the FWP message signal, transmits the FWP signal (15), and the FWP signal gradually increases to a certain level within preset time interval.

 BTS 10 and its neighboring BTS 11, 12 receive the FWP signal. Each BTS registers different values of the delay in time of the RVVP (difference in time of arrival) in accordance with the corresponding distance to the mobile station and the surrounding radio environment.

 In FIG. Figure 3 shows the dependence of the power level of the received FWP signal received by each BTS on the distance. As shown in FIG. 3, pulse (1) (2) (3) (4) FWP, which is transmitted from the mobile station 50 during successive increments with a constant duration (that is, the first pulse is transmitted after 1 ms, the second pulse is transmitted after 2 ms and so on ) In addition, power increases at a fixed increment in each successive time interval (i.e., 10 dB (measured from 1 mW) after 1 ms, 12 dB after 2 ms, 14 dB after 3 ms). Then, the BTS 10, located closest to the mobile station 50, receives a pulse (1) FWP. However, as the distance increases, the impulse (1) of the FWP gradually weakens, and the BTS 11 cannot independently receive the attenuated impulse (1) of the FWP. However, the next transmitted PMF pulse, the PMF pulse (2), is transmitted at a higher level, so that the BTS 11 can receive the PMF pulse (2). Accordingly, the BTS 12 can only receive the impulse (4) of the FWP with the highest level.

 Each BTS 10, 11, and 12 transmits the RVVP to the CKP 30 as the time delay measured for the pulse (4) of the FVP (the most powerful signal), which is received in each BTS. Each BTS also transmits information to calculate the location of the network. The CCP 30 then calculates the location of the mobile station 50 using the RVVP algorithm. The calculated location parameters of the mobile station 50 are then stored in the location database 32.

 The present invention also discloses a method for requesting the provision of a location service using a mobile switching center.

 Since the BTS sends the FWP message to the mobile station, the CCP must make a request for the provision of location services in the BTS through the BSC. The BSC allocates a traffic channel to the mobile station so that the serving BTS and neighboring BTSs from this BTS can receive the FWP signal transmitted by the mobile station.

 That is, in the case when the network operator needs to find out the location of the mobile station or with the help of a subscriber’s request (for example, when the number “911” is dialed in the mobile station), the CCP makes a request for the provision of location services in the BSC. Then, the BSC makes a request for the provision of location services in the BTS, which communicates with the mobile station or BTS, with which the mobile station is not synchronized through the communication channel. Immediately after the establishment of a direct traffic channel, the BTS transmits the FWP message to the corresponding mobile station through the direct traffic channel.

 Regarding the pre-stored list of neighboring BTSs, the BSC issues a command to neighboring BTSs located around the mobile station to allocate a channel to the mobile station using a long pseudo-random noise (PN) code of the mobile station so that neighboring BTSs can receive the FWT signal that will be transmitted using the mobile station. If the channel allocation of neighboring BTSs is completed, the mobile station transmits the FWP signal, and the BTS receives it and then transmits the measured parameters (for example, airspace, delay angle, angle of arrival, and so on) to the CCP.

 In FIG. 4 is a message flow diagram illustrating a request method for providing a location service of a mobile subscriber switching center according to the present invention.

 When the mobile station 50, which communicates with the serving BTS 10 through the traffic channel, issues an emergency ("emergency") call, for example, "119" or when the network operator makes a request for location information for the mobile station 50, the CPU 30 issues a request for location services by transmitting the Loc_Svc_rqst message to the BSC 20 through the communication channel (100) E1.

 Then, BSC 20 makes a request for the provision of traffic channel elements by transmitting the TCE_ Asgn message to neighboring BTSs 11 and 12 from the mobile station in accordance with the request of the CPU 30 (110). At this time, BSC 20 allocates a channel to two or more neighboring BTSs by using a list of neighboring BTSs serving the BTS 10 connected to the mobile station 50 to maintain communication.

 Adjacent BTSs 11 and 12 receive a request for providing traffic channel elements, provide a traffic channel to mobile station 50 using information about mobile station 50, and transmit the corresponding TCE_Asgn_ack response message back to BSC 20 (120).

 The BSC 20 receives a response message from neighboring BTSs 11 and 12 and issues a command to the serving BTS 10 to transmit the FWP message FWP msq by sending a message (FWP msg_rqst to the serving BTS 10 when communicating with the mobile station 50 (130). The FWP msg_rqst message includes information that it is necessary to transmit to the mobile station 50 using the BTS 10, that is, information about the level increment to increase the PF signal (for example, a 2 dB increment, a 4 dB increment, and so on) and the time interval for transmitting the PF signal.

 The serving BTS 10 transmits a message of the FWP, FWP_msg message to the mobile station 50 through a pre-connected traffic channel (140). The mobile station 50 responds to the transmission of the FWP signal in accordance with the information included in the received FWP_msq message (150). The FWP message signal includes a power level interval, a time interval, a transmission time, and so on.

 Then, the serving BTS 10 and neighboring BTSs 11, 12, each of which has a traffic channel connected to the mobile station 50, receive the FWP signal with various time delays. If one or more BTSs from neighboring BTSs 11, 12 did not receive the FWP signal for a certain time interval (that is, the interval determined by the second timer), the BTS releases the traffic channel and stops the second timer.

 That is, the second timer is activated immediately after the neighboring BTS receives a request to allocate a channel from the BSC and stops when it receives the FWP signal from the mobile station.

 If all the BTSs 10, 11 and 12 receive the FWP signal, the BTSs 10, 11 and 12 transmit location parameters, such as the time delay measured for the FWP signal to the MSC 30 through the BSC 20, and the MSC 30 calculates the location of the mobile station in accordance with the received location parameters (160).

 At this time, when the number of BTSs responding is less than two, for example, one BTS located among other BTSs connecting the traffic channel to the mobile station to provide the location service, the BTS releases the traffic channel due to the completion of the second timer, the location of the mobile station cannot be calculated. As a result, BSC 20 should issue a fault message to the MSC 30 or a request to re-allocate the traffic channel to at least one BTS that did not transmit a location parameter message.

 BSC 20, which received the Loc_Svc_rqst message in operation (100), activates the first timer. The first timer is activated after the BSC receives the Loc_Svc_rqst message from the DPC, and stops at the time when it receives the Loc_Svc_rqst or Loc_Svc_Complete message for the same mobile station from the DPC.

 If the Loc_Svc_rqst message for the same mobile station 50 is received from the MSC 30 before the completion of the first timers, then the BSC 20 makes a request to allocate a communication channel again to neighboring BTSs 11 and 12 (170) and repeat steps 110-150. If the Loc_Svc_rqst message is not received before the completion of the first timer, the BSC 20 ends the provision of location services and the first timer.

 And if the Loc_Svc_Cmpt message (that is, the completion of the location service) is transmitted from the CPU 30 before the first timer is completed, the BSC 20 issues a command to release the channel by transmitting the TCE_ release message to neighboring BTSs 11 and 12 and ends the service ( 180) positioning.

Timer description
Although timers have been described in general, a more complete description is made in the context of a message passing scheme (FIG. 4).

 1. The first timer is located within the BSC and starts working at the time when it receives the Loc_Svc_rqst message from the CCP and exits at the time when it receives the Loc_Svc_rqst or Loc_ Svc_Complete messages from the CCP for the same mobile station.

 2. The second timer is located in the BTS and starts at the time when it receives the TCE_asgn message to provide location services from the BSC and ends at the time when it receives the PWF signal from the mobile station.

 3. The third timer is located in the mobile station and starts working at the point in time when it receives the message FVP_msq from the BTS and terminates at the point in time when it transmits the signal FVP to the BTS.

 In FIG. 5 is a diagram illustrating operations of a request method for providing a location service of a mobile subscriber switching center according to a second embodiment of the present invention.

 As stated above, a preferred embodiment of the present invention provides a mobile station with the ability to provide location services using the FWP signal in accordance with IS-95B. The method includes an operation for initiating a request for providing a location service with a CCU and confirming a request for a location service in the BSC. As a result, the present invention makes it possible to predominantly calculate the location of the mobile station without the need for a separate positioning system, instead of using the existing known mobile communication system.

 Although the invention is subject to various modifications and alternative forms, its specific embodiments are shown by way of example with reference to the drawings and are described in detail herein. However, it should be understood that it does not serve to limit the invention disclosed in particular forms, but rather to encompass all modifications, equivalents, and variations without departing from the spirit and scope of the invention as disclosed in the claims.

Claims (14)

 1. The location system for a mobile communication system designed to determine the location of a mobile station, comprising at least three base transceiver stations (BPS) for receiving a signal with a power-on function (FWP) transmitted from a mobile station (PS), and for detecting parameters necessary for determining the location of the mobile station, and the switching center of mobile subscribers (CCP) for receiving the detected parameters from at least three base transceiver stations (BTS), ex sistent in that the MSC comprises means for calculating a mobile station position by combining the received parameters.  2. A method for providing a location service for a mobile communication system, wherein the mobile communication system includes a serving base transceiver station (BTS) communicating with a mobile station, at least two adjacent BTSs located adjacent to the serving BTS, a base station controller (BSC), the manager of the serving BTS and neighboring BTSs, and a mobile subscriber switching center (CSC), connecting the BSC to a public switched telephone network (PSTN), namely, that send a request for the provision of a location service from the CSC to the BSC, make a request from the CSC to allocate a channel for the mobile station in neighboring BTSs using the BSC in accordance with the request of the CSC to provide the location service, connect the dedicated channel to the mobile station and send a response signal to BSC using neighboring BTSs, responding to a request from BSC to allocate a channel, issue a command serving BTS to request the FWP signal from the mobile station using BSC after receiving a response signal, in instruct the mobile station to transmit the FWP signal using the serving BTS, responsive to the command request the FWP signal coming from the BSC, transmit the FWP signal to the serving BTS and neighboring BTS using the mobile station, which responds to the command to transmit the FWP from the serving BTS, detect the parameters requested by the serving BTS and neighboring BTSs, using the received FVP signal transmitted from the mobile station, each FVP signal being transmitted with a different time delay, give a message to the BSC GOVERNMENTAL parameters via the serving BTS and the neighboring BTSs transmit the detected parameters received via the BSC to MSC, calculated position of the mobile station by the MSC using the detected parameters.  3. The method according to claim 2, characterized in that the MSC receives a request for the provision of location services from one mobile station and a network operator.  4. The method according to claim 3, characterized in that the first timer is activated after the BSC receives the request for the provision of location services from the MSC, and stops when the MSC again requests the provision of one of the location services for the mobile station, and when a message is issued the completion of the location service for the mobile station.  5. The method according to claim 4, characterized in that the request for allocation of a channel from at least two BTSs includes, among all BTSs included in neighboring BTSs, a list of serving BTSs.  6. The method according to claim 5, characterized in that the operation of issuing a command to the serving BTS to request the FWP signal using the BSC includes sending BSC information about the FWP signal to the serving BTS that meets the IS-95B standard.  7. The method according to claim 6, characterized in that the information on the FWP signal includes a power level interval, a time interval and a transmission time.  8. The method according to claim 2, characterized in that it further comprises the operation of releasing, with the aid of a neighboring or neighboring BTS, a predetermined channel between the mobile station and the neighboring or neighboring BTSs, wherein the neighboring or neighboring BTSs do not receive the FWP signal if at least one the neighboring BTS does not receive the FWP signal within a predetermined period of time, which is determined using the second timer, after the mobile station transmits the FWP signal.  9. The method according to claim 8, characterized in that it further comprises the operation of returning to the channel allocation request operation for the mobile station in neighboring BTSs, if the MSC makes an additional request for providing location services for the mobile station within the first predetermined time interval, wherein the first predetermined time interval is determined from the point in time when the CSC makes a request to the BSC for the provision of location services to the point in time when the BSC receives a signal from abandonment of the location service.  10. The method according to claim 9, characterized in that the first timer is additionally started immediately after the base station controller receives a request for the provision of location services from the switching center of mobile subscribers, the first timer is started again if the switching center of mobile subscribers is again makes a request for the provision of location services for the switching center of mobile subscribers before the completion of the first timer, and complete the provision of location services I'm using a base station controller if the first timer quits.  11. The method according to claim 10, characterized in that it further comprises the operation of completing the location service if the MSC requests to complete the provision of the positioning service within the first predetermined time interval since the MSC has requested the BSC to provide the location service location.  12. The method according to claim 11, characterized in that the detected parameters are the time delays of the FWP signal, which are measured in each BTS.  13. The method according to p. 12, characterized in that the operation of transmitting parameters to the CCP additionally comprises the operation of issuing a fault message to the CCP if the number of BTSs that issued messages about the detected parameters to the BSC is less than or equal to two.  14. The method according to item 13, wherein the operation of transmitting parameters to the CCP further comprises the operation of issuing a command of at least one BTS, which did not give messages about the detected parameters, to re-establish the preset channel in the mobile station using the BSC if the number of BTSs that issued messages on detected parameters to the BSC is less than or equal to two.

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